Neuronal effects of epicranial current stimulation in macaque cortex.

IF 3.2 3区医学 Q2 NEUROSCIENCES

Frontiers in Neuroscience Pub Date : 2025-09-23 eCollection Date: 2025-01-01 DOI:10.3389/fnins.2025.1627705

Boateng Asamoah, Ahmad Khatoun, Maria C Romero, Elsie Premereur, Peter Janssen, Myles Mc Laughlin

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引用次数: 0

Abstract

Background: Transcranial electrical stimulation (TES) using scalp electrodes is noninvasive, safe and inexpensive. However, because the scalp shunts most of the current, electric fields (E-fields) in the brain are relatively weak. Conversely, invasive neuromodulation methods such as deep brain stimulation (DBS) and invasive cortical stimulation (ICS) successfully treat many brain diseases. However, the expensive and risky surgery limits the reach of these approaches. Epicranial current stimulation (ECS), where electrodes are implanted on the skull, is a novel approach which can bridge the gap between these two extremes. In current study we investigated the effects of ECS on neural activity.

Methods: In two macaque monkeys we implanted two concentric ring electrodes directly on the skull. Each electrode targeted one area PFG (PFG is not an acronym; rather it is the full name of a particular part of the parietal cortex) of the parietal convexity. Furthermore, a craniotomy was drilled in the skull to access the same area PFG. While recording (2 min) we stimulated (during the second recording minute) with a 10 or 40 Hz sinewave using an unfocused montage (between two electrodes on each side of the head) or a focused (through the concentric electrodes) over an intensity range of 0.25 to 4 mA. These two montages allowed us to investigate neural responses to targeted and broad brain stimulation. Furthermore, in a functional magnetic resonance imaging (fMRI) experiment we stimulated, at only 10 Hz, through an unfocused montage.

Results: Our results show that E-field strengths depended on a combination of montage and stimulation intensity. Depending on the montage stimulation caused entrainment as well as spike rate increases. For focused stimulation and unfocused stimulation at lower amplitudes neural activity became entrained to the stimulation (similar to TES). For the unfocused stimulation, as stimulation amplitude increased, spike-rates also increased (similar to ICS and DBS) while the unfocused did not affect spike rates. The fMRI study showed a distributed pattern of activations which is suggestive of a network response caused by ECS.

Conclusion: ECS has been used as a proxy for transcutaneous stimulation in rodent setups. Here we show that as a standalone technique it can be applied to a larger and more complex brain. This makes it a promising neuromodulation approach with clinical applications in patients who do not respond to TES but are not yet candidates for ICS or DBS.

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外颅电流刺激对猕猴皮层神经元的影响。

背景：使用头皮电极的经颅电刺激（TES）无创、安全、廉价。然而，由于头皮分流了大部分电流，大脑中的电场（E-fields）相对较弱。相反，侵入性神经调节方法，如深部脑刺激（DBS）和侵入性皮层刺激（ICS）成功地治疗了许多脑部疾病。然而，昂贵和高风险的手术限制了这些方法的应用范围。颅外电流刺激（ECS）是一种新颖的方法，将电极植入颅骨，可以弥合这两个极端之间的差距。本研究探讨了体外刺激对神经活动的影响。方法：在两只猕猴颅骨上直接植入两个同心圆环形电极。每个电极针对顶叶凸出的一个区域PFG （PFG不是首字母缩写，而是顶叶皮层特定部分的全称）。此外，颅骨开颅钻孔进入PFG的同一区域。在记录（2 min）时，我们使用无聚焦蒙太奇（在头部两侧的两个电极之间）或聚焦（通过同心电极）在0.25至4 mA的强度范围内刺激（在第二个记录分钟内）10或40 Hz的正弦波。这两个蒙太奇使我们能够研究神经对目标和广泛的大脑刺激的反应。此外，在功能性磁共振成像（fMRI）实验中，我们通过无聚焦蒙太奇以仅10 Hz的频率进行刺激。结果：我们的研究结果表明，电场强度取决于蒙太奇和刺激强度的组合。根据蒙太奇刺激引起的夹带以及尖峰率的增加。对于聚焦刺激和低振幅的非聚焦刺激，神经活动被刺激所吸引（类似于TES）。对于非聚焦刺激，随着刺激幅度的增加，峰值速率也会增加（类似于ICS和DBS），而非聚焦刺激对峰值速率没有影响。fMRI研究显示了一种分布式的激活模式，这表明了由ECS引起的网络反应。结论：ECS已被用作啮齿动物经皮刺激的替代方法。在这里，我们展示了作为一种独立的技术，它可以应用于更大更复杂的大脑。这使得它成为一种有希望的神经调节方法，可用于临床应用于对TES无反应但尚未适合ICS或DBS的患者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Neuroscience NEUROSCIENCES-

CiteScore

6.20

自引率

4.70%

发文量

2070

审稿时长

14 weeks

期刊介绍： Neural Technology is devoted to the convergence between neurobiology and quantum-, nano- and micro-sciences. In our vision, this interdisciplinary approach should go beyond the technological development of sophisticated methods and should contribute in generating a genuine change in our discipline.